Your search keyword '"Yafeng Deng"' showing total 13 results

1. Multi-modal deep learning enables efficient and accurate annotation of enzymatic active sites

Author

Xiaorui Wang, Xiaodan Yin, Dejun Jiang, Huifeng Zhao, Zhenxing Wu, Odin Zhang, Jike Wang, Yuquan Li, Yafeng Deng, Huanxiang Liu, Pei Luo, Yuqiang Han, Tingjun Hou, Xiaojun Yao, and Chang-Yu Hsieh

Subjects

Science

Abstract

Abstract Annotating active sites in enzymes is crucial for advancing multiple fields including drug discovery, disease research, enzyme engineering, and synthetic biology. Despite the development of numerous automated annotation algorithms, a significant trade-off between speed and accuracy limits their large-scale practical applications. We introduce EasIFA, an enzyme active site annotation algorithm that fuses latent enzyme representations from the Protein Language Model and 3D structural encoder, and then aligns protein-level information with the knowledge of enzymatic reactions using a multi-modal cross-attention framework. EasIFA outperforms BLASTp with a 10-fold speed increase and improved recall, precision, f1 score, and MCC by 7.57%, 13.08%, 9.68%, and 0.1012, respectively. It also surpasses empirical-rule-based algorithm and other state-of-the-art deep learning annotation method based on PSSM features, achieving a speed increase ranging from 650 to 1400 times while enhancing annotation quality. This makes EasIFA a suitable replacement for conventional tools in both industrial and academic settings. EasIFA can also effectively transfer knowledge gained from coarsely annotated enzyme databases to smaller, high-precision datasets, highlighting its ability to model sparse and high-quality databases. Additionally, EasIFA shows potential as a catalytic site monitoring tool for designing enzymes with desired functions beyond their natural distribution.

Published

2024

2. Strain-tunable lattice and energy gap in bulk black phosphorus

Author

Yafeng Deng, Yafei Zhao, Yongkang Xu, Xingze Dai, Shuanghai Wang, Kun He, Yongbing Xu, and Liang He

Subjects

Physics, QC1-999

Abstract

This study employs an optimized model to investigate the lattice deformation and band structure evolutions induced by the tensile strain along the zigzag direction of bulk black phosphorus (bulk BP) and the physical mechanisms behind it. It has been found that the tensile strain leads to the lattice expansion along the zigzag direction, while contracting along the armchair direction, and the out-of-plane lattice undergoes sequential expansion and contraction. This is also accompanied by an increasing and decreasing of the bulk energy gap and eventually reaching zero. Furthermore, one hopping factor has been proposed to connecting the interlayer spacing and the interlayer interaction, which successfully explains the strain-induced evolutions of the bulk energy gap. This work provides a theoretical reference for the strain-induced band engineering of bulk BP.

Published

2024

3. Enhancing Generic Reaction Yield Prediction through Reaction Condition-Based Contrastive Learning

Author

Xiaodan Yin, Chang-Yu Hsieh, Xiaorui Wang, Zhenxing Wu, Qing Ye, Honglei Bao, Yafeng Deng, Hongming Chen, Pei Luo, Huanxiang Liu, Tingjun Hou, and Xiaojun Yao

Subjects

Science

Abstract

Deep learning (DL)-driven efficient synthesis planning may profoundly transform the paradigm for designing novel pharmaceuticals and materials. However, the progress of many DL-assisted synthesis planning (DASP) algorithms has suffered from the lack of reliable automated pathway evaluation tools. As a critical metric for evaluating chemical reactions, accurate prediction of reaction yields helps improve the practicality of DASP algorithms in the real-world scenarios. Currently, accurately predicting yields of interesting reactions still faces numerous challenges, mainly including the absence of high-quality generic reaction yield datasets and robust generic yield predictors. To compensate for the limitations of high-throughput yield datasets, we curated a generic reaction yield dataset containing 12 reaction categories and rich reaction condition information. Subsequently, by utilizing 2 pretraining tasks based on chemical reaction masked language modeling and contrastive learning, we proposed a powerful bidirectional encoder representations from transformers (BERT)-based reaction yield predictor named Egret. It achieved comparable or even superior performance to the best previous models on 4 benchmark datasets and established state-of-the-art performance on the newly curated dataset. We found that reaction-condition-based contrastive learning enhances the model’s sensitivity to reaction conditions, and Egret is capable of capturing subtle differences between reactions involving identical reactants and products but different reaction conditions. Furthermore, we proposed a new scoring function that incorporated Egret into the evaluation of multistep synthesis routes. Test results showed that yield-incorporated scoring facilitated the prioritization of literature-supported high-yield reaction pathways for target molecules. In addition, through meta-learning strategy, we further improved the reliability of the model’s prediction for reaction types with limited data and lower data quality. Our results suggest that Egret holds the potential to become an essential component of the next-generation DASP tools.

Published

2024

4. Chemistry-intuitive explanation of graph neural networks for molecular property prediction with substructure masking

Author

Zhenxing Wu, Jike Wang, Hongyan Du, Dejun Jiang, Yu Kang, Dan Li, Peichen Pan, Yafeng Deng, Dongsheng Cao, Chang-Yu Hsieh, and Tingjun Hou

Subjects

Science

Abstract

Abstract Graph neural networks (GNNs) have been widely used in molecular property prediction, but explaining their black-box predictions is still a challenge. Most existing explanation methods for GNNs in chemistry focus on attributing model predictions to individual nodes, edges or fragments that are not necessarily derived from a chemically meaningful segmentation of molecules. To address this challenge, we propose a method named substructure mask explanation (SME). SME is based on well-established molecular segmentation methods and provides an interpretation that aligns with the understanding of chemists. We apply SME to elucidate how GNNs learn to predict aqueous solubility, genotoxicity, cardiotoxicity and blood–brain barrier permeation for small molecules. SME provides interpretation that is consistent with the understanding of chemists, alerts them to unreliable performance, and guides them in structural optimization for target properties. Hence, we believe that SME empowers chemists to confidently mine structure-activity relationship (SAR) from reliable GNNs through a transparent inspection on how GNNs pick up useful signals when learning from data.

Published

2023

5. ReMODE: a deep learning-based web server for target-specific drug design

Author

Mingyang Wang, Jike Wang, Gaoqi Weng, Yu Kang, Peichen Pan, Dan Li, Yafeng Deng, Honglin Li, Chang-Yu Hsieh, and Tingjun Hou

Subjects

Deep learning, De novo drug design, Molecular generation, Adversarial autoencoders, Transfer learning, Artificial intelligence, Information technology, T58.5-58.64, Chemistry, QD1-999

Abstract

Abstract Deep learning (DL) and machine learning contribute significantly to basic biology research and drug discovery in the past few decades. Recent advances in DL-based generative models have led to superior developments in de novo drug design. However, data availability, deep data processing, and the lack of user-friendly DL tools and interfaces make it difficult to apply these DL techniques to drug design. We hereby present ReMODE (Receptor-based MOlecular DEsign), a new web server based on DL algorithm for target-specific ligand design, which integrates different functional modules to enable users to develop customizable drug design tasks. As designed, the ReMODE sever can construct the target-specific tasks toward the protein targets selected by users. Meanwhile, the server also provides some extensions: users can optimize the drug-likeness or synthetic accessibility of the generated molecules, and control other physicochemical properties; users can also choose a sub-structure/scaffold as a starting point for fragment-based drug design. The ReMODE server also enables users to optimize the pharmacophore matching and docking conformations of the generated molecules. We believe that the ReMODE server will benefit researchers for drug discovery. ReMODE is publicly available at http://cadd.zju.edu.cn/relation/remode/ . Graphical Abstract

Published

2022

6. Generic Interpretable Reaction Condition Predictions with Open Reaction Condition Datasets and Unsupervised Learning of Reaction Center

Author

Xiaorui Wang, Chang-Yu Hsieh, Xiaodan Yin, Jike Wang, Yuquan Li, Yafeng Deng, Dejun Jiang, Zhenxing Wu, Hongyan Du, Hongming Chen, Yun Li, Huanxiang Liu, Yuwei Wang, Pei Luo, Tingjun Hou, and Xiaojun Yao

Subjects

Science

Abstract

Effective synthesis planning powered by deep learning (DL) can significantly accelerate the discovery of new drugs and materials. However, most DL-assisted synthesis planning methods offer either none or very limited capability to recommend suitable reaction conditions (RCs) for their reaction predictions. Currently, the prediction of RCs with a DL framework is hindered by several factors, including: (a) lack of a standardized dataset for benchmarking, (b) lack of a general prediction model with powerful representation, and (c) lack of interpretability. To address these issues, we first created 2 standardized RC datasets covering a broad range of reaction classes and then proposed a powerful and interpretable Transformer-based RC predictor named Parrot. Through careful design of the model architecture, pretraining method, and training strategy, Parrot improved the overall top-3 prediction accuracy on catalysis, solvents, and other reagents by as much as 13.44%, compared to the best previous model on a newly curated dataset. Additionally, the mean absolute error of the predicted temperatures was reduced by about 4 °C. Furthermore, Parrot manifests strong generalization capacity with superior cross-chemical-space prediction accuracy. Attention analysis indicates that Parrot effectively captures crucial chemical information and exhibits a high level of interpretability in the prediction of RCs. The proposed model Parrot exemplifies how modern neural network architecture when appropriately pretrained can be versatile in making reliable, generalizable, and interpretable recommendation for RCs even when the underlying training dataset may still be limited in diversity.

Published

2023

7. An Investigation into the Multi-Pass Radial-Mode Micro Abrasive Air Jet Turning of Fused-Silica Rods

Author

Ruibo Yang, Quanlai Li, Weipeng Zhang, Yafeng Deng, and Jialin Li

Subjects

micro abrasive air jet, multi-pass turning, waviness, striation, material removal rate, depth of cut, Mechanical engineering and machinery, TJ1-1570

Abstract

With the increased requirement of miniaturization structures on hard and brittle substrates, micro abrasive air jet turning technology has become a promising machining technology for manufacturing miniaturization structures. This paper presents an investigation on multi-pass radial-mode micro abrasive air jet turning of fused silica. The effect of machining parameters on the depth of cut and materials removal rate was analyzed. The waviness and striation formation mechanisms were studied. It was found that increasing the number of passes significantly increases the depth of cut and materials removal rate. When the surface speed is reduced, the depth of cut and materials removal rate significantly increases. The waviness may be attributed to the intersection and overlap of the adjoint jet footprint. The crossed striations have been found, which may lead to the elimination of the striation. A predictive model of the material removal rate was developed using the dimensional analysis method. The model was assessed and shown to be able to give adequate predictions.

Published

2023

8. Unlocking comprehensive molecular design across all scenarios with large language model and unordered chemical language.

Author

Jie Yue, Bingxin Peng, Yu Chen, Jieyu Jin, Xinda Zhao, Chao Shen, Xiangyang Ji, Chang-Yu Hsieh, Jianfei Song, Tingjun Hou, Yafeng Deng, and Jike Wang

Published

2024

9. Preparation of N/S doped carbon dots and their application in nitrite detection.

Author

Yafeng Deng, Jun Qian, Yihua Zhou, and Yifan Niu

Published

2021

10. Rotor position estimation method of permanent magnet synchronous motor based on high frequency signal injection and sliding mode observer.

Author

Hui Wang, Changsong Wang, Yafeng Deng, Zhiyu Wang, and Hongxia Liu

Published

2010

11. Fast Face Detection Integrating Motion Energy into a Cascade-Structured Classifier.

Author

Yeung, Daniel S., Zhi-Qiang Liu, Xi-Zhao Wang, Hong Yan, Yafeng Deng, Guangda Su, Jun Zhou, and Bo Fu

Abstract

In this paper, we propose a fast and robust face detection method. We train a cascade-structured classifier with boosted haar-like features which uses intensity information only. To speed up the process, we integrate motion energy into the cascade-structured classifier. Motion energy can represent moving the extent of the candidate regions, which is used to reject most of the candidate windows and thus accelerates the evaluation procedure. According to the face presence situation, we divide the system state into three modes, and process input images with an intensity detector, or motion integrated dynamic detector, or else keep the pre-results. Since motion energy can be computed efficiently, processing speed is greatly accelerated. Furthermore, without depending on any supposed motion model, the system is very robust in real situations without the limitation of moving patterns including speed and direction. [ABSTRACT FROM AUTHOR]

Published

2006

12. A Dynamic Face and Fingerprint Fusion System for Identity Authentication.

Author

Yue Hao, Jiming Liu, Yu-Ping Wang, Yiu-ming Cheung, Hujun Yin, Licheng Jiao, Jianfeng Ma, Yong-Chang Jiao, Jun Zhou, Guangda Su, Yafeng Deng, Kai Meng, and Congcong Li

Abstract

This paper presents a novel dynamic face and fingerprint fusion system for identity authentication. To solve the face pose problem in dynamic authentication system, multi-route detection and parallel processing technology are used in this system. A multimodal part face recognition method based on principal component analysis (MMP-PCA) algorithm is adopted to perform the face recognition task. Fusion of face and fingerprint by SVM (Support Vector Machine) fusion strategy which introduced a new normalization method improved the accuracy of identity authentication system. Furthermore, key techniques such as fast and robust face detection algorithm and dynamic fingerprint detection and recognition method based on gray-Level histogram statistic are accepted to guarantee the fast and normal running. Practical results on real database proved that this authentication system can achieve better results compared with face-only or fingerprint-only system. Consequently, this system indeed increases the performance and robustness of identity authentication systems and has more practicability. [ABSTRACT FROM AUTHOR]

Published

2005

13. Effect of Bi2S3 reaction concentration on the photoelectric properties of TiO2/Bi2S3 composite film.

Author

Di Zhu, Xinli Li, Yongchao Chen, Yafeng Deng, Dao Chen, Yuwan Wang, and Fengzhang Ren

Published

2019